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31 |
Biologically Inspired Omniphobic Surfaces by Reverse Imprint Lithography
Enthalten in Advanced materials Bd. 26, 2014, Nr. 13: 2029-2033. 5 S.
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32 |
Functional Surfaces: Biologically Inspired Omniphobic Surfaces by Reverse Imprint Lithography (Adv. Mater. 13/2014)
Enthalten in Advanced materials Bd. 26, 2014, Nr. 13: 2028-2028. 1 S.
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33 |
Material and Technological Development of Natural Fiber Reinforced Cellulose Acetate Butyrate †
Enthalten in Advanced engineering materials Bd. 16, 2014, Nr. 10: 1202-1207. 6 S.
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34 |
Tunable nano-replication to explore the omniphobic characteristics of springtail skin
Hensel, R.. - London : Macmillan Publishers, 2013
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35 |
Smart skin patterns protect springtails
Helbig, R.. - San Francisco, CA : Public Library of Science, 2011
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36 |
Der Lotus‐Effekt: Selbstreinigung mikrostrukturierter Oberflächen
Enthalten in Nachrichten aus der Chemie Bd. 48, 2010, Nr. 1: 24-28. 5 S.
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37 |
Psammophora and other sand‐coated plants from southern Africa
Enthalten in Feddes Repertorium Bd. 107, 2008, Nr. 5‐6: 549-555. 7 S.
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38 |
Phylogeny of the Genus Peperomia (Piperaceae) Inferred from the trnK/matK Region (cpDNA)
Enthalten in Plant biology Bd. 8, 2006, Nr. 01: 93-102
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39 |
Two-Dimensional Tension Tests in Plant Biomechanics - Sweet Cherry Fruit Skin as a Model System
Enthalten in Plant biology Bd. 6, 2004, Nr. 04: 432-439
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40 |
Der Lotus‐Effekt: Künstliche selbstreinigende Oberflächen nach biologischen Vorbild
Enthalten in Chemie - Ingenieur - Technik Bd. 72, 2000, Nr. 9: 972-973. 2 S.
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